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Base editing and nanoparticle transfection of airway cell types essential for treatment of cystic fibrosis
Erin W. Kavanagh, Anya T. Joynt, Audrey R. Pion, Alice C. Eastman, Alianna I. Parr, Katherine L. Starego, Manav Jain, Sydney R. Shannon, Edwin J. Yoo, Gregory A. Newby, Stephany Y. Tzeng, Neeraj Sharma, Jordan J. Green, Garry R. Cutting
Erin W. Kavanagh, Anya T. Joynt, Audrey R. Pion, Alice C. Eastman, Alianna I. Parr, Katherine L. Starego, Manav Jain, Sydney R. Shannon, Edwin J. Yoo, Gregory A. Newby, Stephany Y. Tzeng, Neeraj Sharma, Jordan J. Green, Garry R. Cutting
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Research Article Clinical Research Genetics

Base editing and nanoparticle transfection of airway cell types essential for treatment of cystic fibrosis

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Abstract

Cystic fibrosis (CF) is a life-limiting genetic disorder caused by deleterious variants in the CFTR gene that results in altered mucus impairing the airway epithelia. Durable correction of these variants in airway cells remains a therapeutic challenge for about 10% of individuals unresponsive to CFTR modulators. A common disease-causing CFTR splice site variant, 3120+1G>A, was corrected in primary CF airway cells using base editor RNAs. Single-cell RNA sequencing revealed a remarkable increase in detectable CFTR transcript in most CF airway epithelial cell types resulting in notable enrichment of CFTR-expressing ionocytes and secretory goblet cells. Progenitor basal cell subtypes were edited, but they decreased as a fraction of total cells and CFTR-expressing cells compared with unedited cells. CRISPR base editors delivered by polymeric nanoparticles (PNPs) facilitated functional rescue of CFTR to clinically meaningful levels in immortalized and primary airway cells. PNPs delivered GFP-encoding RNA to progenitor airway cells in fully differentiated airway cultures. Vitronectin was a major component of the PNP corona that formed in vivo, but preincubation with vitronectin did not enhance delivery. Together, these findings validate a scalable, nonviral platform with compelling translational promise for treating CF and other respiratory diseases involving respiratory epithelial cell dysfunction.

Authors

Erin W. Kavanagh, Anya T. Joynt, Audrey R. Pion, Alice C. Eastman, Alianna I. Parr, Katherine L. Starego, Manav Jain, Sydney R. Shannon, Edwin J. Yoo, Gregory A. Newby, Stephany Y. Tzeng, Neeraj Sharma, Jordan J. Green, Garry R. Cutting

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Figure 1

Single-cell transcriptome atlas of primary HNE cells from a CF donor bearing the variants 3120+1G>A/G480S corrected with an ABE.

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Single-cell transcriptome atlas of primary HNE cells from a CF donor bea...
(A) Schema of primary HNE cell collection, electroporation, and differentiation period on air-liquid interface. Cells underwent electroporation and delivery of ABE8e and sgRNA (4long or 5long) before undergoing differentiation for 21 days, and then were processed for scRNA-seq. (B) Fluorescent microscopy images taken 24 hours after electroporation of ABE8e mRNA/no sgRNA (left) and GFP mRNA (right) with bright-field (top) or GFP (bottom). Scale bars: 1,000 μm. (C) Quantification of gDNA A-to-G nucleotide conversion (% G) at the 3120+1G>A target site. Dashed line represents 50% G nucleotide content to indicate contribution of G sequence from the G480S allele in trans. Values were determined using the Sanger sequencing deconvolution program EditR (64). Data are shown as mean ± SEM (N = 2). (D) Violin plot comparing CFTR expression levels in CFTR+ cells only across edited and unedited samples. P value was determined by 1-way ANOVA followed by Tukey’s multiple-comparison test. **P ≤ 0.01. (E) UMAPs separated by edited (N = 4 [sg4long N = 2, sg5long N = 2]; 13,305 cells) or unedited (N = 2 [control]; 9,906 cells) samples. (F) UMAP detailing CFTR expression across all cellular subtypes.

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